Magnetic recording medium

Abstract

A magnetic recording medium is disclosed, which comprises a support having thereon a magnetic layer comprising a binder and a ferromagnetic powder dispersed therein, wherein said binder comprises a polyurethane resin having at least one cyclic hydrocarbon group and at least one ether linkage, and said ferromagnetic powder is a ferromagnetic metallic powder which comprises Fe and has a mean major-axis length of from 0.05 to 0.19 .mu.m and a crystallite size of from 100 to 230 .ANG.; and further a magnetic recording medium is disclosed, comprising a support having thereon in succession an undercoat layer comprising a binder U and an inorganic powder dispersed therein and a magnetic layer comprising a binder M and a ferromagnetic powder dispersed therein, wherein at least either of the binder U or M comprises a polyurethane resin having at least one cyclic hydrocarbon group and at least one ether linkage and said ferromagnetic powder is a ferromagnetic metallic powder which comprises Fe and has a mean major-axis length of from 0.05 to 0.19 .mu.m and a crystallite size of from 100 to 230 .ANG..

Description

FIELD OF THE INVENTIONThe present invention relates to a magnetic recording medium which comprises a non-magnetic support having thereon a magnetic layer in which a ferromagnetic fine powder and a binder are dispersed, and which has especially good electromagnetic characteristics and durability.BACKGROUND OF THE INVENTIONThe magnetic recording medium is widely used as audio tapes for recording sound, video tapes, or tapes or floppy disks for recording computer data. The magnetic recording medium of these types has on a support a magnetic layer containing a ferromagnetic powder dispersed in a binder.The magnetic recording medium is required to be on high levels with respect to various characteristics, including electromagnetic characteristics, running durability and running performance. More specifically, the audio tapes for reproducing recorded music are required to have a higher level of original sound-reproducing ability; while the video tapes are required to have excellent electr...

AI Technical Summary

Benefits of technology

Therefore, an object of the present invention is to provide a magnetic recording medium which has a high level of durability and excellent electromagnetic characteristics, including excellent reproducing output.

In a magnetic recording medium according to the first embodiment, by using a particular polyurethane resin, which has the cyclic hydrocarbon group and ether linkage, as at least a part of a binder, and further using in combination therewith a specified ferromagnetic powder which has high potential, excellent electromagnetic characteristics can be obtained. Use of the polyurethane resin as defined above enables the ferromagnetic powder to be dispersed more satisfactorily than ever; as a result, the magnetic recording medium comes to have a very high squareness ratio and low SFD (Switching Field Distribution): and, at the same time, the magnetic recording medium having an excellent running durability can be obtained.

With respect to a magnetic recording medium according to the second embodiment, the undercoat layer provided therein enables a greater reduction in the thickness of a magnetic layer formed thereon; as a result, the magnetic recording medium can have further improved electromagnetic characteristics. In accordance with the second embodiment, a magnetic recording medium undergoing improvements in electromagnetic characteristics and running durability can be obtained even when the aforesaid particular polyurethane resin is used as at least a part of the binder in the undercoat layer alone. For a reason of the improvements, it is assumed that the inorganic powder can be dispersed more satisfactorily than ever in the undercoat layer to enhance the smoothness of the magnetic layer surface. Of course, it is most desirable for the second embodiment to use the aforesaid particular polyurethane resin as at least a part of the binder in both the magnetic layer and the undercoat layer.

Problems solved by technology

Therefore, an improvement of running durability due to use of abrasives often causes deterioration in the above-described electromagnetic characteristics.

In a case where lubricants are used for improvement of the aforementioned running durability, a large amount of the lubricants added is required.

As a result, the magnetic layer is subject to deterioration in durability because the binder comes to have a tendency to be plasticized.

Conventional binders, such as polyvinylchloride resins, cellulose resins, polyurethane resins and acrylic resins, have a problem in that the magnetic layers using them are inferior in abrasion resistance to result in soiling the parts of a magnetic tape-running system such as

Accordingly, such a binder ensures excellent durability, but has a disadvantage in that it causes a viscosity increase of the coating solution which is accompanied by the lowering of dispersibility to deteriorate the electromagnetic characteristics.

Since the cyclic hydrocarbon groups in a resin lower the resin's solubilities in solvents, the polyurethane resin of the foregoing type has a drawback of being inferior in dispersibility.

The proportions of bisphenol A and the polyol in such a polyurethane resin are evaluated to be 16 weight % and 63 weight %, respectively, by the calculation from the data in Example of the above-cited reference, and so this polyurethane resin also has a problem that its dispersibility is lowered due to the solubility-lowering effect of the cyclic hydrocarbon groups present therein.

Accordingly, such a polyurethane resin also has the same problem as mentioned above because of the presence of the cyclic hydrocarbon groups therein.

As a result, those coated film suffer from disadvantages of soiling a magnetic head and having low durability.

Thus, such resins also have problems of soiling a magnetic head and deteriorating the durability.

In addition, such a resin is attended by lowering of strength and deterioration in repeated running properties due to the presence of branched polyols therein.

Although this reference describes only use of a polyesterpolyol, the binder obtained still has the resin strength-lowering problem and the problem of causing deterioration in repeated running properties.

However, the resins prepared therein are insufficient in resin strength and repeated running durability.

However, the hydrophilic segments in the above-recited polyurethane resins and polyurethaneurea resins hinder the resins from having affinity for organic solvents, and the hydrophilic polar groups are subject to aggregation; as a result, the resins show a weak tendency to stretch their molecular chains in an organic solvent.

Thus, the presence of hydrophilic segments in the resins acts adversely on the dispersion of a ferromagnetic fine powder.

In addition, those second diols having hydrophilic segments are attended by drawbacks that, when they are polyesters, the polyurethane resins obtained have inferior storage stability because of ester linkage's liability to hydrolysis; while, when they are polyethers such as polytetramethylene ether glycol, polypropylene glycol and polyethylene glycol, the polyurethane resins obtained are soft and have low Tg to form films having low strength.

The fine pulverization of a ferromagnetic metal powder causes the lowering of dispersibility to result in deterioration in surface quality and electromagnetic characteristics of the magnetic layer, and further to make it difficult for the magnetic layer to secure the durability.

Although the tapes utilizing vacuum deposited thin films of ferromagnetic metals (ME) are available at present as 8-mm video tapes and video tapes appropriate to DVC (which stands for a digital video camera) for consumer use, ferromagnetic metal powder-coated tapes (MP) have an advantage of being superior to ME in durability and economic efficiency, but on the other hand they are inferior to ME in electromagnetic characteristics.